Ionization device, mass spectrometry apparatus, mass spectrometry method, and imaging system

ABSTRACT

A mass spectrometry apparatus includes a holding table that holds a specimen to be ionized, a probe that identifies a portion of the specimen to be ionized, an ion extraction electrode that extracts ions obtained by ionizing the specimen, a liquid supplying unit that supplies liquid to between the specimen and the probe to form a liquid bridge between the specimen and the probe, a vibrating unit that vibrates one of the probe and the holding table, an electric field generating unit that generates an electric field between the probe and the ion extraction electrode, a mass spectrometry unit that mass analyzes ions extracted by the ion extraction electrode, and a synchronization unit configured to synchronize a time at which ions are generated from the portion with a time at which the mass spectrometry unit measures the ions.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation, and claims the benefit, of U.S.patent application Ser. No. 14/446,771, presently pending and filed onJul. 30, 2014, and claims the benefit of Japanese Patent Application No.2013-161331 filed Aug. 2, 2013, and Japanese Patent Application No.2013-183962 filed Sep. 5, 2013, which applications are herebyincorporated by reference herein in their entireties.

BACKGROUND

1. Field of the Invention

The present invention relates to an ionization device and a massspectrometry apparatus for ionizing a specimen and mass analyzing aspecimen.

2. Description of the Related Art

For analysis of component in a surface of a solid specimen, a technologyfor ionizing a solid substance in an atmospheric pressure environmenthas been developed.

For example, such a technique is described in the following non-patentliterature: Yoichi Otsuka et al., “Scanning probe electrosprayionization for ambient mass spectrometry” Rapid Communications in massspectrometry, 26, 2725 (2012). In the technique, a small volume of thesolvent is deposited onto a microregion of a surface of a solidspecimen, and a component of the specimen is dissolved in the solvent.Thereafter, the component is ionized by electrospray ionization.Generated ions are introduced into a mass spectrometry apparatus, whichmeasures the mass-to-charge ratio of the ion. Thus, the component can beanalyzed. To deposit the solvent onto the microregion of the surface ofthe solid specimen, a probe formed from a needle-like capillary is used.The solvent is continuously fed to the probe. A liquid bridge is formedbetween the probe and the surface of the solid specimen that is locatedin close proximity to the probe. The component contained in the surfaceof the solid specimen is dissolved into the liquid bridge. The solventhaving the component dissolved therein is ionized by applying a voltageto the solvent. The probe is vibrated and, thus, the solvent that iscontinuously supplied to the surface of the solid specimen is ionized.Such a technique is referred to as Tapping-mode Scanning ProbeElectrospray Ionization (Tapping-mode SPESI). In contrast, a techniquefor ionizing the solvent with the probe remaining in close proximity tothe surface of the solid specimen is referred to as Contact-modeScanning Probe Electrospray Ionization (Contact-mode SPESI).

In the Tapping-mode SPESI described in non-patent literature above, aliquid bridge is alternately formed and disrupted. In the technique,dissolution of a component into the liquid bridge and ionization of thecomponent are alternately and continuously performed. The frequency ofthe formation of the liquid bridge and the ionization is determined bythe frequency of vibration of the probe. In addition, the massspectrometry apparatus is electrically separated from an ionizationdevice. The mass spectrometry apparatus and the ionization device areindependently driven. The ions introduced into the mass spectrometryapparatus are measured within a predetermined measurement period oftime.

In the technique, measurement using mass spectrometry is performed evenduring a period of time during which ionization is not performed, thatis, during a period of time during which a liquid bridge is being formedand during a period of time during which ions are being generated afterthe liquid bridge is formed.

As a result, a noise signal generated when ionization is not performedis mixed with measurement data, which makes mass spectral analysis ofthe data difficult.

In addition, it is difficult to finely control the number of ionizationprocesses performed within the measurement time of ionization, thequantitative capability of measurement is low and, thus, thequantitative capability when the measurement values each measured in onemeasurement process are compared with one another is low.

In contrast, in terms of Contact-mode SPESI, a technique for steadilyvibrating a substrate having a solid specimen placed thereon isproposed. In such a technique, vibration of the substrate makesionization stable. However, measurement of ions is performed during anentire period of vibration time of the substrate, a noise signalgenerated during a period of time during which ionization is notactually performed is mixed in measurement data. In addition, when thesubstrate is steadily vibrated for a long time, a device for generatingthe vibration is heated. The heat may cause the amplitude and thefrequency of the vibration to fluctuate.

SUMMARY

The present disclosure provides an ionization device and the massspectrometry apparatus capable of measuring the component distributionin a microregion of a surface of a specimen in an atmospheric pressureenvironment with a high sensitivity.

According to an aspect of the present disclosure, an ionization deviceincludes a holding table configured to hold a specimen to be ionized, aprobe configured to identify a portion of the specimen to be ionized, anion extraction electrode configured to extract ions obtained by ionizingthe specimen, a liquid supplying unit configured to supply liquid tobetween the specimen and the probe to form a liquid bridge between thespecimen and the probe, a vibrating unit configured to vibrate one ofthe probe and the holding table, an electric field generating unitconfigured to generate an electric field between the probe and the ionextraction electrode, and a synchronization unit configured toperforming at least one of the following two synchronization processeson the basis of vibration of the probe or the holding table:

(i) synchronizing a time at which ions are generated from the portionwith a time at which a mass spectrometry unit for mass analyzing theions extracted by the ion extraction electrode measures the ions, and

(ii) synchronizing vibration of the probe with vibration of the holdingtable.

According to another aspect disclosed herein, a mass spectrometryapparatus includes a holding table configured to hold a specimen to beionized, a probe configured to identify a portion of the specimen to beionized, an ion extraction electrode configured to extract ions obtainedby ionizing the specimen, a liquid supplying unit configured to supplyliquid to between the specimen and the probe to form a liquid bridgebetween the specimen and the probe, a vibrating unit configured tovibrate one of the probe and the holding table, an electric fieldgenerating unit configured to generate an electric field between theprobe and the ion extraction electrode, a mass spectrometry unitconfigured to mass analyze ions extracted by the ion extractionelectrode, and a synchronization unit configured to synchronize a timeat which ions are generated from the portion with a time at which themass spectrometry unit measures the ions.

According to the present disclosure, an ionization device capable ofmeasuring the component distribution of a microregion of a surface of aspecimen in an atmospheric pressure environment with a high sensitivityand a mass spectrometry apparatus or an imaging system including theionization device are provided.

Further features of the present invention will become apparent from thefollowing description of exemplary embodiments with reference to theattached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic illustration of an imaging system including anionization device according to a first exemplary embodiment

FIG. 2 is a timing diagram illustrating the operation timing of each ofapparatuses in a first drive mode of the ionization device according tothe first exemplary embodiment.

FIG. 3 is a timing diagram illustrating the operation timing of each ofapparatuses in a second drive mode of the ionization device according tothe first exemplary embodiment.

FIG. 4 is a timing diagram illustrating the operation timing of each ofapparatuses in a third drive mode of the ionization device according tothe first exemplary embodiment.

FIG. 5 is a schematic illustration of a synchronization circuit andapparatuses controlled by the synchronization circuit in a third drivemode of an ionization device according to a second exemplary embodiment.

FIG. 6 is a schematic illustration of an imaging system including theionization device according to the third exemplary embodiment.

FIGS. 7A and 7B are timing diagrams of the operation timing ofapparatuses in first and second drive modes of the ionization deviceaccording to the third exemplary embodiment.

FIG. 8 is a timing diagram of the operation timing of apparatuses in athird drive mode of the ionization device according to the thirdexemplary embodiment.

FIG. 9 is a timing diagram of the operation timing of apparatuses in thefirst to third drive modes of the ionization device according to thethird exemplary embodiment.

DESCRIPTION OF THE EMBODIMENTS First Exemplary Embodiment

FIG. 1 is a schematic illustration of an imaging system including anionization device according to the first exemplary embodiment of thepresent invention. The imaging system includes a probe 1 having a flowpassage therein, where the flow passage allows liquid to flow through, avibration providing unit 2 that vibrates the probe 1, a solid specimen3, a liquid bridge 4 formed between the probe 1 and the solid specimen3, a Taylor cone 5, charged fine liquid droplets 6, an ion entrapmentunit 7 including an ion extraction electrode for entrapping ions into amass spectrometry apparatus, an XY stage 8 serving as a holding tablethat holds the solid specimen 3, a Z stage 9 for moving the solidspecimen 3 in a Z direction (the vertical direction in FIG. 1), specimenstage control devices 10 and 11, a voltage applying apparatus 12, aliquid supply unit 13 that supplies liquid to the probe 1, a voltageapplying apparatus 14, light sources 15 and 19, displacement sensors 16and 20 serving as measurement units that measure displacement, a massspectrometry unit 17, a voltage applying apparatus 18, an ion counter21, an image forming unit 22, a displacement calculation device 23, anda display unit 24.

The ion counter 21 is incorporated into the mass spectrometry unit 17and be used. Alternatively, instead of being incorporated into the massspectrometry unit 17, the ion counter 21 may be externally connected tothe mass spectrometry unit 17 and be used. In either case, the number ofions entrapped in the mass spectrometry unit 17 can be measured. Inaddition, the ion counter 21 includes an input terminal of a gatesignal. By inputting an appropriate signal to the input terminal of agate signal, driving of the ion counter 21 can be controlled.

An ion detector (e.g., a microchannel plate detector) and an electricsignal measuring device (e.g., an analog-to-digital converter (ADC) or atime-to-digital converter (TDC)) can be used as the ion counter 21. Inaddition, a device for adjusting the waveform of the electric signal(e.g., a discriminator or an amplifier circuit) may be provided betweenthe ion detector and a measuring instrument of the electric signal. Theinput terminal of a gate signal is incorporated into the measuringinstrument of the electric signal.

The liquid supply unit 13 supplies the solvent for dissolving acomponent to be analyzed contained in the solid specimen 3 or mixedsolution of a component to be analyzed and the solvent (hereinafter, thesolvent and the mixed solution are collectively and simply referred toas “liquid”). The liquid supplied from the liquid supply unit 13 is ledto the flow passage in the probe 1. At that time, a voltage is appliedto the liquid by the voltage applying apparatus 14. The voltage appliedto the liquid is one of a DC voltage, an AC voltage, a pulse voltage,and a zero volt.

According to the present exemplary embodiment, the liquid supplied fromthe liquid supply unit 13 forms the liquid bridge 4 between the solidspecimen 3 and the probe 1. At that time, the solid specimen 3 is anobject formed from an object to be measured that is placed on one of ametal substrate, an electrically insulating material substrate, and asemiconductor substrate, and the object to be measured requires that thecomponent distribution in the microregion of the object is measured.Examples of the object include a biological tissue and bodily fluid.However, the object may be an object other than a biological tissue andbodily fluid.

In addition, the liquid that forms the liquid bridge 4 is turned intothe fine liquid droplets 6 by the vibration of the probe 1, and the fineliquid droplets 6 are charged by the electric field generated by thevoltage applying apparatus 14 and the voltage applying apparatus 18.Thus, the component of the object to be measured can be entrapped in theion entrapment unit 7 in the form of ions. That is, according to thepresent exemplary embodiment, the probe 1 functions as a supply unit forsupplying the liquid onto the substrate, a substance acquiring unit, atransport unit for transporting the liquid to a position that issuitable for ionization, and a forming unit for forming a Taylor conefor ionization.

Note that according to the present exemplary embodiment, an electricallyconductive probe has such a configuration that provides electricalconductivity to the flow passage and a connection pipe in the probe 1and that allows a voltage to be applied to the liquid contained in theprobe 1. To achieve such a structure, it is desirable that anelectrically conductive member be disposed in the entire or part of theflow passage that is in contact with the liquid.

However, the electrically conductive member is not necessarily disposedin the flow passage and the connection pipe inside the probe 1. It isonly required that the structure allows the liquid contained in the topend portion of the probe 1 to be charged before the liquid reaches thetop end of the probe, that is, the electrically conductive member can belocated in a mid-top end portion.

To achieve the suitable configuration of the probe 1, at least part ofthe material of the probe 1 has electrical conductivity. Examples ofsuch a material include a metal and a semiconductor. However, anymaterial that has a property generating a reproducible constant voltagecan be used. That is, according to the present exemplary embodiment, avoltage is applied to the liquid by applying a voltage to a conductiveportion of the probe 1.

As used herein, the term “application of voltage to a probe” is used todenote a process to apply an electric potential that differs from theelectric potential of an ion extraction electrode (described in moredetail below) to a conductive portion that constitutes at least part ofthe probe and generate an electric field between the conductive portionand the ion extraction electrode. As long as the electric field isgenerated, the applied voltage may be zero volt. The material of atleast part of the probe 1 should be electrically conductive. Forexample, a stainless steel, gold, or platinum can be used as thematerial.

For example, a tubule, such as a silica capillary or a metal capillary,capable of supplying a small volume of liquid can be used as each of theprobe 1 and the connection pipe that connects the probe 1 to the liquidsupply unit 13. The tubule may have the same electric conductivity asany one of an insulating material, a conductor, and a semiconductor.Note that the electrically conductive flow passage should be at leastpart of the flow passage that allows the liquid supplied from the liquidsupply unit 13 to pass through inside of the probe 1 and reach the topend of the probe 1 on the opposite side of the liquid supply unit 13.The position of the electrically conductive flow passage is not limitedto any particular position of the probe 1. For example, the entire orpart of the electrically conductive flow passage may be included in theflow passage or the connection pipe inside the probe 1.

If the probe 1 itself is electrically conductive, the voltage applied bythe voltage applying apparatus 14 propagates through the probe 1 and isapplied to the liquid in the flow passage inside the probe 1. Incontrast, if the probe 1 is made of an electrically insulating material,the voltage applied to the electrically conductive flow passage does notpropagate to the probe 1. At that time, the voltage is applied to theliquid flowing in the electrically conductive flow passage, and theliquid enters the probe 1. Accordingly, even when the voltage is notpropagated to the probe 1, the voltage can be applied to the liquid.Thus, the liquid is charged.

The liquid supplied from the liquid supply unit 13 is provided from thetop end of the probe 1 onto the solid specimen 3. In this manner, aminutely small amount of the substance contained in the solid specimen 3can be dissolved into the liquid and be ionized in an atmosphericpressure environment.

In the above-described configuration according to the present exemplaryembodiment, the probe 1 can be vibrated. According to the presentexemplary embodiment, the vibration of the probe 1 is the periodicmotion of the probe 1 such that the position of the top end of the probe1 adjacent to the solid specimen 3 is spatially displaced. Inparticular, it is desirable that the probe 1 be bending-vibrated in adirection crossing the axis direction of the probe 1. To vibrate theprobe 1, mechanical vibration is provided from the vibration providingunit 2 to the probe 1. In addition, by stopping supply of vibration fromthe vibration providing unit 2, the vibration of the probe 1 can bestopped.

In general, the natural resonance frequency in a primary mode of acantilevered object can be expressed by using the length, the density,the cross sectional area, the Young's modulus, and the second moment ofarea of the cantilever. Since the needle-like probe 1 according to thepresent exemplary embodiment is similar to a cantilevered probe, thenatural resonance frequency of the probe 1 can be controlled bycontrolling the material and the size of the probe 1, the type andvolume of the liquid supplied to the probe 1, and the magnitude of theelectric field generated between the probe 1 and the ion entrapment unit7. Examples of the material of the probe 1 include, but not limited to,silica, silicon, a polymer material, and a metal material.Alternatively, a probe formed by joining two or more materials havingdifferent densities and Young's moduli may be used. In addition, anydevice that generates vibration can be used as the vibration providingunit 2. For example, a piezoelectric device or a vibration motor may beused as the vibration providing unit 2. Vibration of the probe 1 may beeither continuous vibration or intermittent vibration. The timing atwhich the voltage is applied to the liquid and the timing at whichvibration is provided to the probe 1 may be determined as needed.

In addition, the solvent may be supplied from the liquid supply unit 13through a flow passage formed in the surface of the probe 1. Forexample, a minutely small groove may be formed in the surface of theprobe 1. By using capillarity, the solvent introduced from the liquidsupply unit 13 may flow in the surface of the probe 1 and reach the topend portion of the probe 1.

Although the configuration in which the liquid supply unit 13 isphysically connected to the probe 1 is illustrated in FIG. 1, the liquidsupply unit 13 may be spatially separated from the probe 1. For example,by using an inkjet technique, the solvent may be ejected from the liquidsupply unit 13 spatially separated from the probe 1 to the probe 1 andbe deposited onto the probe 1.

The frequency and amplitude of the vibration of the probe 1 may be setto desired values. The values may be constant values or modulatedvalues. For example, by varying a voltage value or a frequency valueoutput from the voltage applying apparatus 12 that is electricallyconnected to the vibration providing unit 2, the amplitude and frequencyof the vibration of the probe 1 can be adjusted to the desired values.

The Z stage 9 is physically connected to the XY stage 8 and the solidspecimen 3. The Z stage 9 is used to vibrate the solid specimen 3 in thevertical direction. The Z stage 9 can vibrate a specimen on the basis ofa control signal output from the specimen stage control devices 11connected to the Z stage 9. The frequency and amplitude of the vibrationmay be set to desired values. The values may be constant values ormodulated values. In such a case, by varying the voltage value or thefrequency value output from the specimen stage control devices 11, thefrequency and amplitude of the vibration can be adjusted to the desiredvalues.

At that time, the XY stage 8 may be fixed onto the Z stage 9.Alternatively, the Z stage 9 may be fixed onto the XY stage 8.

The light source 15 and the displacement sensor 16 are used to measurethe vibration of the probe 1. The light source 15 and the displacementsensor 16 are disposed so that a spot light ray formed by collecting thelight emitted from the light source 15 is reflected by the probe 1 andis led to the displacement sensor 16. By detecting the position of thereflected spot light ray using the displacement sensor 16, the frequencyand amplitude of the vibration of the probe 1 can be measured. Examplesof the light source 15 include a laser light source, a halogen lightsource, and a light emitting diode (LED) light source. In addition, oneof a lens and a pinhole that collects light or one of a cylindrical lensand a slit that collect light into a line shape may be disposed in frontof the light source 15. Like the light source 15 and the displacementsensor 16, the light source 19 and the displacement sensor 20 are usedto measure the vibration of the XY stage 8 and the vibration of the Zstage 9.

In this example, a light source and a displacement sensor are used tomeasure the vibration of the probe 1, the XY stage 8, and the Z stage 9.However, instead of the light source and the displacement sensor,another type of displacement sensor may be used. Examples of anothertype of displacement sensor include an electrostatic capacitancedisplacement sensor, an eddy current displacement sensor, a laserDoppler displacement sensor, and a piezoelectric displacement sensor. Inthe case of an electrostatic capacitance displacement sensor, a portionhaving electric conductivity can be formed in each of the probe 1, theXY stage 8, and the Z stage 9. The vibration can be measured bydetecting the variation of the electrostatic capacitance between theportion and the sensor. In the case of an eddy current displacementsensor, an eddy current generated in a metal which is part of each ofthe probe 1, the XY stage 8, and the Z stage 9 is measured from avariation of the inductance of a coil of the sensor that generates analternating-current magnetic field. Since the variation of theinductance depends on the distance between the sensor and the metal, thevibration can be measured. In the case of a laser Doppler displacementsensor, the vibration can be measured by detecting the frequency ofreflected light when a laser beam is emitted to the probe 1, the XYstage 8, and the Z stage 9. In the case of a piezoelectric displacementsensor, the vibration can be measured by detecting the pressure appliedto a piezoelectric device in contact with each of the probe 1, the XYstage 8, and the Z stage 9 in the form of a voltage signal.

The electric signals output from the displacement sensor 16 and thedisplacement sensor 20 are input to the displacement calculation device23. The frequency, amplitude, and phase of the vibration of the probeand the stage can be measured using the electric signals.

According to the present exemplary embodiment, a vibration unit thatvibrates the probe is independent from a vibration unit that vibratesthe specimen. Accordingly, the following three vibratory modes can beprovided as a drive mode. That is, the three vibratory modes are (A) amode for vibrating the probe, (B) a mode for vibrating the solidspecimen, and (C) a mode for independently vibrating the probe and thesolid specimen at the same time.

FIG. 1 is a schematic illustration when the drive mode (A) or (C) isselected. In the drive mode (B), provision of a signal from the voltageapplying apparatus 12 to the vibration providing unit 2 is stopped, andthe probe 1 is located in close proximity to a solid specimen or is incontact with the solid specimen.

In the drive mode (A) in which the probe 1 is vibrated, a signal isinput to the vibration providing unit 2, and provision of a signal tothe specimen stage control device 11 is stopped. As a result, the probe1 vibrates, and the vibration of the Z stage 9 is stopped.

In the drive mode (B) in which the solid specimen is vibrated, provisionof a signal to the vibration providing unit 2 is stopped, and a signalis input to the specimen stage control device 11. As a result, the probe1 is stopped, and the Z stage 9 vibrates. If the probe 1 is in contactwith a surface of the solid specimen 3, vibration of the Z stage 9propagates to the probe 1. Accordingly, the probe 1 can be vibrated.Even in such a case, the drive mode (B) is applied.

In the drive mode (C) in which the probe 1 and the solid specimen 3 areindependently vibrated, a signal is input to the vibration providingunit 2. At the same time, a signal is input to the specimen stagecontrol device 11. As a result, the probe 1 and the Z stage 9independently vibrate.

FIG. 2 is a timing diagram illustrating the operation timing of each ofthe apparatuses in the drive mode (A) of the ionization device accordingto the first exemplary embodiment. In the timing diagram, a waveformchart (a) illustrates the voltage value of a trigger signal formeasurement performed by the ion counter 21, a waveform chart (b)illustrates the voltage value of a vibration signal for the probe 1, anda waveform chart (c) illustrates the gate voltage value input to the ioncounter 21. In general, the ion counter 21 operates so as tointermittently receive the trigger signal for the mass spectrometry unit17 and, after receiving the trigger signal, count the number of ions.The type of trigger signal differs in accordance with the configurationof an ion separation unit of the mass spectrometry unit 17. According tothe present exemplary embodiment, for example, a quadrupole massspectrometer, a time-of-flight mass spectrometer, a magnetic sector massspectrometer, or an ion-trap mass spectrometer can be used as the massspectrometry unit 17. In addition, the trigger signal may be generatedat a particular timing for each of the types of mass spectrometer.

For example, in quadrupole mass spectrometers, a signal indicating apoint in time at which application of a high-frequency voltage to thequadrupole is started may be used as the trigger signal. Intime-of-flight mass spectrometers, a signal indicating a point in timeat which a pulse voltage for accelerating the speed of ions in a devicefor measuring the flight time of the ions is applied may be used as thetrigger signal. In magnetic sector mass spectrometers, a signalindicating a point in time at which application of a magnetic field to asector electrode is started may be used as the trigger signal. Inion-trap mass spectrometers, a signal indicating a point in time atwhich ions are entrapped in an ion trap may be used as the triggersignal. In general, the frequency of the pulse voltage of atime-of-flight mass spectrometer is in the range of several KHz toseveral tens of kHz. In addition, the frequency of ion entrapmentperformed by an ion-trap mass spectrometer is in the range of severaltens Hz to several kHz. That is, in general, the frequencies are higherthan the frequency of vibration of a probe.

The probe 1 vibrates, and formation of a liquid bridge and ionizationare alternately performed. The frequency of vibration of the probe 1 isin the range of hundred Hz to tens of KHz. In FIG. 2, the frequency ofthe trigger signal of the mass spectrometry unit 17 is 20 times thefrequency of vibration of the probe 1. At a time 1, the probe 1 islocated so as to be in close proximity to or in contact with the solidspecimen 3 and, thus, a liquid bridge is formed between the probe 1 andthe surface of the solid specimen 3. In addition, at a time 2, the probe1 is moved away from the solid specimen 3 and comes close to the ionentrapment unit 7, where ionization is performed. A gate voltage value(c) input to the ion counter 21 is synchronized with the voltage value(b) of the signal for vibrating the probe 1. The output gate voltagevalue (c) is set so as to be turned ON in a given time window around thetime 2 of the voltage value (b) of the signal for vibrating the probe 1.At that time, a duration 3 is defined as a period of time during whichions are generated. The duration 3 can be set to a desired value. Thegate voltage value (c) that is output is input to the input terminal ofa gate signal of the ion counter 21. The ion counter 21 is operated onlywhen the gate voltage value (c) is being output. As a result, only forthe period of time indicated by the “duration 3”, during which ions aregenerated by the probe 1, the ion counter 21 can be operated.Accordingly, during a period of time during which the liquid bridge isformed and during a period of time from the time the liquid bridge isformed to the time ions are generated, a noise signal is not measured.In this manner, a noise signal included in a measurement data signal canbe reduced.

In the above-described example, when the duration 3 is set, the voltagevalue (b) of a vibration signal for the probe 1 is defined as areference signal for regulating a period of time during whichelectrospray ionization is performed, and the gate voltage value (c)that is synchronized with the reference signal is used. Note that if asignal indicating the displacement of the top end portion of the probe 1is synchronized with the probe vibration signal, the signal output fromthe displacement sensor 16 may be used as the reference signal insteadof the voltage value (b) of the signal for vibrating the probe 1.Alternatively, if a phase difference exists between the signal forvibrating the probe 1 and the signal indicating the displacement of thetop end portion of the probe 1, either the probe vibration signal or thedisplacement signal may be selected as the reference signal. Thereafter,by adjusting the rise time and the fall time of the gate voltage value(c) that is synchronized with the reference signal, the phase differencemay be compensated for.

FIG. 3 is a timing diagram illustrating the operation timing of each ofthe apparatuses in the drive mode (B) of the ionization device accordingto the first exemplary embodiment. In the timing diagram, a triggersignal (a) for measurement performed by the ion counter 21 connected tothe mass spectrometry unit 17, a vibration signal (b) for the Z stage 9,and the gate voltage signal (c) input to the ion counter 21 areillustrated. The vibration signal input to the Z stage 9 is modulated soas to be alternately turned ON and OFF for a predetermined period oftime. Ions are more stably generated in a duration 2 than in a duration1 for which the Z stage 9 is not vibrated. By modulating the vibrationof the Z stage 9 in this manner, heat generated when the Z stage 9 isvibrated at high speed (at 1 KHz or higher) can be advantageouslyreduced. If the Z stage 9 is continuously vibrated, the Z stage 9 isoverheated and, thus, the amplitude of the vibration may be decreased ormalfunction of the Z stage 9 may occur. Accordingly, it is desirablethat a modulating operation be performed to reduce the vibration time.In this manner, a cooling time period of the Z stage 9 can be provided.If the Z stage 9 is continuously vibrated, it is desirable that anadditional cooling mechanism of the Z stage 9 be provided. Note that ifa signal that is not modulated is used, setting should be performed sothat the duration 1 is not present and the duration 3 in which ions arestably generated is considered as a duration in which ions aregenerated.

The gate voltage signal (c) is set so as to be output in synchronizationwith the duration 2 in which the vibration signal (b) for the Z stage 9is generated. The gate voltage signal (c) is input to the input terminalof a gate signal of the ion counter 21. As a result, only for the periodof time for which ions are stably generated by the probe 1, the ioncounter 21 can be operated. Accordingly, a noise signal generated duringa period of time until ionization is performed is not measured. In thismanner, a noise signal included in a measurement data signal can bereduced.

In FIG. 3, a single pulse having a duration 2 is illustrated. However,the gate signal may be modulated in synchronization with the vibrationsignal (b). That is, pulse signals each having a duration that is lessthan the duration 2 and synchronizing with the positive or negative peakof the vibration signal (b) may be used.

In addition, when the duration 2 is set, the voltage value of thevibration signal (b) for vibrating the Z stage 9 is defined as thereference signal for determining the period of time during whichelectrospray ionization is performed, and the gate voltage signal (c)that is synchronized with the reference signal is used. However, thesignal output from the displacement sensor 20 may be used as thereference signal instead of the voltage value of the vibration signal(b).

FIG. 4 is a timing diagram illustrating the operation timing of each ofthe apparatuses in the drive mode (C) of the ionization device accordingto the first exemplary embodiment. In the timing diagram, a triggersignal (a) for measurement performed by the ion counter 21 connected tothe mass spectrometry unit 17, a vibration signal (b) for the probe 1, avibration signal (c) for the Z stage 9, and a gate signal “d” input tothe ion counter 21 are illustrated. The frequency of vibration of the Zstage 9 is set so as to be one fifth of the frequency of vibration ofthe probe 1. As described above, it is desirable that one of the twofrequencies of vibration be an integer multiple of the other frequencyand, in addition, the phase difference between the vibrations be 0 or180 degrees. At the time 1, the probe 1 is in close proximity to or incontact with the solid specimen 3, and a liquid bridge is formed betweenthe probe 1 and a surface of the solid specimen 3. At the time 2, theprobe 1 is located so as to be the farthest from the solid specimen 3.After the liquid bridge is formed at the time 1 and before the nextliquid bridge is formed, ionization is performed. The gate signal (d) issynchronized with the vibration signal (b) or the vibration signal (c).The gate signal (d) is set so as to be turned ON within a predeterminedperiod of time immediately before the time 1. The duration 3 for whichthe gate signal (d) is ON is defined as a time period during which ionsare generated. The duration 3 can be set to any value. As a result, theion counter 21 is operated only when ions are stably generated from theprobe 1. Thus, a noise signal generated during a period of time duringwhich a desired component is not ionized is not measured. In thismanner, a noise signal included in a measurement data signal can bereduced.

According to the present exemplary embodiment, in addition to advantagesthat are the same as in the above-described drive modes (A) and (B), anadvantage that the absolute value of the distance between the probe 1and the Z stage 9 is increased due to vibrations of both the probe 1 andZ stage 9 can be provided. Note that when the irregularity of thesurface profile of the solid specimen 3 is significant and, thus, thevibration amplitude of the probe 1 needs to be increased so thatformation of the liquid bridge and ionization are stably performed, itis desirable that the present exemplary embodiment be applied. While thepresent exemplary embodiment has been described with reference to thecontrol signals of the specimen stage control device 11 and the voltageapplying apparatus 12 being a triangle wave, a sine wave, or a squarewave, the waveform is not limited thereto. For example, the waveform maybe a sawtooth waveform or a waveform obtained by combining a trianglewave, a sine wave, a square wave, and a sawtooth wave illustrated inFIG. 2.

According to the present exemplary embodiment, when the duration 3 isset, the voltage value (b) of a vibration signal for the probe 1 isdefined as a reference signal for regulating a period of time duringwhich electrospray ionization is performed, and the gate voltage value(c) that is synchronized with the reference signal is used. However,instead of the voltage value (b) of the vibration signal, the signaloutput from the displacement sensor 16 or the displacement sensor 20 maybe used as the reference signal.

In each of the drive modes (A), (B), and (C), the vibration state ismeasured by using the displacement calculation device 23. Thereafter,control signals are output from the displacement calculation device 23to the specimen stage control device 11 and the voltage applyingapparatus 12 so that a desired vibration state is obtained. Thevibration state corresponds to an ion generation period for whichelectrospray ionization is performed and a non-ion generation period.Accordingly, the displacement calculation device 23 can be used tomeasure a period of time during which ions are generated throughelectrospray ionization.

For example, a period of time for which each of the voltages of the ACsignals output from the displacement sensor 16 and the displacementsensor 20 is higher than a threshold voltage is measured as a period oftime for which ionization is well performed. The measurement can beperformed by measuring the signals output from the sensors using anoscilloscope or a circuit for generating a vibration control signal of aprobe and a circuit for generating a vibration control signal of a solidspecimen. Note that such circuits are included in a gate signalgeneration circuit (described in more detail below).

The threshold voltage can be set to any value. The threshold voltage isset to detect a period of time for which the probe 1 is located in closeproximity to the ion entrapment unit 7 or a period of time for which theXY stage 8 and the Z stage 9 are vibrating. A voltage pulse is outputfrom a waveform generator or the gate signal generation circuit(described in more detail below) in synchronization with a period oftime for which ionization is well performed. The voltage pulse is inputto the input terminal of a gate signal of the ion counter 21.

If a feedback circuit is provided in the displacement calculation device23, the displacement calculation device 23 can automatically maintainstable vibration. When the probe 1 scans the solid specimen 3, a slightvariation of the frequency or the amplitude may occur. At that time, bymeasuring a shift of a signal output from each of the displacementsensor 16 and the displacement sensor 20 from a reference signal thatcan be set in the displacement calculation device 23, generating asignal that corrects the shift, and outputting the signal to thespecimen stage control device 11 and the voltage applying apparatus 12,stable scan can be performed. Note that the reference signal is a signalhaving a desired waveform used to determine the frequency and theamplitude of vibration of each of the probe 1 and the Z stage 9.

In addition, a slight timing shift may occur between the vibration ofthe probe 1 and the vibration of the Z stage 9 due to, for example,electrical wiring between the components and the electric capacitancesof the components illustrated in FIG. 1. In such a case, by providing adelay circuit that controls the timing in the displacement calculationdevice 23, the timing shift between the vibration of the probe 1 and acontrol signal and the timing shift between the vibration of the Z stage9 and a control signal can be compensated for.

According to the present exemplary embodiment, by selecting one of thedrive modes (A), (B), and (C), the following processes are alternatelyperformed: (i) a process to supply liquid from a probe onto a solidspecimen and form a liquid bridge between the probe and the solidspecimen, and (ii) a process to generate an electric field forgenerating ions between the conductive portion of the probe in contactwith the liquid and an ion extraction electrode. That is, by changingthe position of one end of the probe that vibrates, the position of theprobe can be set to the position optimum for performing each of theprocesses (i) and (ii).

By intermittently or continuously providing the liquid from the probe 1,the liquid bridge 4 is formed. When the liquid bridge 4 is formed, theprobe 1 may or may not be in contact with the solid specimen 3. If theprobe 1 is in contact with the solid specimen 3, the liquid bridge 4 canbe formed more reliably. The liquid bridge 4 is formed from liquid thatbridges between 1 and the solid specimen 3. The liquid bridge 4 isformed by using, for example, the surface tension. A substance containedin the solid specimen 3 is dissolved in the liquid bridge 4. The liquidbridge 4 is formed in an atmospheric pressure environment. The volume ofthe liquid bridge 4 is minutely small and is approximately 1×10-12 mL.The liquid bridge 4 is located in part of the surface of the solidspecimen 3. The dimensions of the part of the surface of the solidspecimen 3 is approximately 1×10-8 m2.

When the probe 1 moves away from the solid specimen 3 due to thevibration, liquid that forms the liquid bridge 4 moves closer to the ionentrapment unit 7 including the ion extraction electrode electricallyconnected to the voltage applying apparatus 18. At that time, the liquidmoves to the side surface of the probe 1 adjacent to the ion entrapmentunit 7 to form the Taylor cone 5 due to the potential difference betweenthe electric potential of the liquid having the voltage applied theretoand the electric potential of the ion extraction electrode having thevoltage applied by the voltage applying apparatus 18 (preferably 0.1 kVor higher and 10 kV or lower and, more preferably, 3 kV or higher and 5kV or lower). As used herein, the term “side surface” refers to aportion of the probe 1 in which the electrospray occurs. In FIG. 1, theTaylor cone 5 is formed on a continuous surface that forms the long axisdirection of the probe 1. However, since this location is influenced by,for example, the electric field generated between the ion entrapmentunit 7 and the liquid and the wettability of the probe 1 with theliquid, the Taylor cone 5 may be formed at a location that includes asurface other than the above-described surface.

The magnitude of the electric field increases in the top end portion ofthe Taylor cone 5 and, thus, electrospray is generated from the mixedsolution. Accordingly, fine charged liquid droplets 6 are generated. Bysetting the magnitude of the electric field to an appropriate value,Rayleigh breakup of the charged liquid droplets occurs and, thus, ionsof a particular component can be generated. The charged liquid dropletsand the ions are led to the ion entrapment unit 7 by the airflow and theelectric field. At that time, in order to increase the electric field inthe vicinity of the solvent that forms the Taylor cone, it is desirablethat vibration of the probe 1 include the motion to move close to theion entrapment unit 7.

Note that the term “Rayleigh breakup” refers to a phenomenon that whenthe fine liquid droplets 6 reach the Rayleigh limit, excessive charge inthe charged liquid droplets are released in the form of secondary liquiddroplets. It is known that liquid forms a Taylor cone. Electrosprayincluding charged liquid droplets is generated from the top end portionof the Taylor cone. For a period of time for which Rayleigh breakupoccurs, a component contained in the charged liquid droplets turns intogas-phase ions. In addition, a threshold voltage Vc for the occurrenceof the electrospray is given as follows:

Vc=0.863(γd/ε0)^(0.5)

where γ denotes the surface tension of the liquid, d denotes thedistance between the liquid and the ion extraction electrode, and ε0denotes the permittivity of vacuum (refer to J. Mass Spectrom. Soc. Jpn.Vol. 58, 139-154, 2010).

To evaporate the solvent from the charged liquid droplets generatedthrough the electrospray and generate ions, the ion entrapment unit 7 isheated at a particular temperature between a room temperature andseveral hundred degrees. In addition, a voltage is applied to the ionentrapment unit 7. At that time, to generate an appropriate electricfield that generates ions, it is necessary to adjust the voltage that isapplied to the liquid by the voltage applying apparatus 18 serving as anelectric field generating unit and the voltage that is applied to theion extraction electrode by the voltage applying apparatus 18. Examplesof the voltage applied by the voltage applying apparatus 12 include a DCvoltage, an AC voltage, a pulse voltage, zero volt, and any desiredcombinations thereof. Note that the electric field for generating ionsis determined by the electric potential applied to the electricallyconductive portion of the probe 1, the electric potential of the ionentrapment unit 7, and the distance between the liquid and the ionentrapment unit 7. Accordingly, these electric potentials and distanceneed to be set so that an appropriate electric field is generated inaccordance with the type of substance to be ionized and the type ofsolvent.

Subsequently, the ions are introduced into the mass spectrometry unit 17connected to the ion entrapment unit 7 through a differential exhaustsystem, and the mass-to-charge ratio of the ions is measured in the massspectrometry unit 17. Any one of a quadrupole mass spectrometer, atime-of-flight mass spectrometer, a magnetic sector mass spectrometer,an ion-trap mass spectrometer, and an ion-cyclotron mass spectrometercan be used as the mass spectrometry unit 17. In addition, by measuringa correlation between the mass-to-charge ratio (mass number/chargenumber) (hereinafter, referred to as “m/z”) of the ions and the amountof generated ions, the mass spectrum can be obtained.

Furthermore, to fix the specimen onto the substrate and ionize thespecimen, the coordinates of the position of a portion of the specimento be ionized can be controlled by changing the position of the XY stage8 using the specimen stage control device 10. Still furthermore, byassociating the coordinates of the ionized positions (positionalinformation) with the obtained mass spectra, the two-dimensionaldistribution of the mass spectrum can be obtained. Data obtained usingthis technique is three-dimensional data containing the coordinates (anX coordinate and a Y coordinate) of the ionized position and the massspectrum. After the ionization and the mass spectrum acquisition areperformed at different positions, the amount of ions having a desiredmass-to-charge ratio is selected, and the distribution thereof isdisplayed. In this manner, a mass image can be obtained for each of thecomponents, and the distribution of a particular component across thesurface of the specimen can be captured. The specimen can be moved sothat the liquid bridge 4 formed by the probe 1 scans a desired plane ofthe solid specimen 3 to be measured.

The image forming unit 22 identifies a portion of the surface of thesolid specimen 3 to be ionized. That is, the image forming unit 22identifies a portion of the surface of the solid specimen 3 to beanalyzed by the mass spectrometry apparatus. Thereafter, the imageforming unit 22 can move the solid specimen 3 using the XY stage 8 andthe Z stage 9 so that the substance contained in the portion is includedin the Taylor cone 5 via the liquid bridge 4.

Each of the image forming unit 22 and the displacement calculationdevice 23 is formed from, for example, a computer.

The image forming unit 22 receives at least a signal output from the ioncounter 21 and outputs signals to the specimen stage control apparatus10.

The displacement calculation device 23 receives at least a signal outputfrom the displacement sensor 16 and outputs signals to the voltageapplying apparatus 12 and the specimen stage control apparatus 11.

When the probe 1 scans the surface of the solid specimen 3, a movementprocess of the probe 1 and a process of ionization and measurement ofthe number of ions are alternately performed. At that time, by settingup the image forming unit 22 and the displacement calculation device 23,scanning of the probe 1 can be performed after a predetermined number ofionization processes and measurements of the number of ions areperformed. In this manner, the quantitative capability of thethree-dimensional data can be increased and, thus, the amounts of ionsin the mass images at all the coordinates can be quantitatively comparedwith one another. Any scanning unit that allows the probe 1 torelatively scan the surface of the specimen can be used as the scanningunit of the probe 1. That is, either the above-described scanning unitthat moves the specimen stage with the position of the probe 1 fixed ora scanning unit that moves the probe 1 with the position of the specimenstage fixed can be employed.

According to the present exemplary embodiment, the image forming unit 22of the mass spectrometry apparatus generates image information used fordisplaying, as an image, the distribution of a substance contained inthe solid specimen 3 from information regarding the position of thesolid specimen 3 to be analyzed (a portion of the solid specimen 3 to beanalyzed) in the image forming unit 22 and the mass information (themass spectrum) obtained from the ion counter 21 according to theabove-described present exemplary embodiment.

According to the present exemplary embodiment, the imaging systemincludes the mass spectrometry apparatus according to theabove-described present exemplary embodiment and an image display unit.

The image information output from an output sub-unit of the imageforming unit 22 is output to an output unit (the display unit 24, suchas a flat panel display) connected to the image forming unit 22. Thus,the image is displayed. The image information may be two-dimensionalimage information or three-dimensional image information. The outputunit may be a unit that prints an image (e.g., a printer).

As described above, a substance that is dissolved from a particularposition of the solid specimen 3 into the liquid bridge 4 can bedetected on the basis of the result of mass spectrometry at theparticular position of the solid specimen 3. By changing the particularposition in the surface of the solid specimen 3 and performing massspectrometry at the position, mass spectrum data can be obtained. Bycombining the mass spectrum data with the information regarding theparticular position, the distribution of the substance in the solidspecimen 3 (in most cases, the distribution of the substance across thesurface of the solid specimen 3) is obtained and is displayed(superimposed) as an image.

In addition to the position of the substance, the amount of thesubstance is displayed. The amount of the substance is represented by acolor or the brightness of the image. In addition, if multiplesubstances contained in the solid specimen 3 are analyzed, thesubstances can be identified by using different colors, and the amountthereof can be represented by the brightness thereof. Furthermore, apre-captured microscope image of the solid specimen 3 may besuperimposed on the image regarding the mass of the solid specimen 3 andmay be displayed.

Second Exemplary Embodiment

A second exemplary embodiment using a synchronization circuit isdescribed below.

To synchronize the timing of vibration of the probe 1 and the timing ofvibration of the stage with the gate signal, it is desirable to use acircuit for generating a synchronous signal that synchronizes thevibration control signal of the probe 1 with the vibration controlsignal of the stage or that synchronizes the output signal of thedisplacement sensor 16 with the output signal of the displacement sensor20.

FIG. 5 illustrates an example of a synchronization circuit capable ofperforming such control, a device controlled by the output signal outputfrom the synchronization circuit, and a device that generates an inputsignal input to the synchronization circuit.

As illustrated in FIG. 5, the synchronization circuit includes areference clock generating circuit 101, the displacement calculationdevice 23, a signal selection switch 102, and a gate signal generatingcircuit 103. The displacement calculation device 23 includes a circuitfor generating a vibration control signal for a probe and a circuit forgenerating a vibration control signal for the solid specimen.

In addition, the apparatuses that are controlled by the output signaloutput from the synchronization circuit include the voltage applyingapparatus 12, the vibration providing unit 2, the probe 1, the specimenstage control device 11, the Z stage 9, and a data acquiring device 108.The data acquiring device 108 is formed from an ion counter 104, aprimary memory 105, a data filter 106, and a storage 107.

Furthermore, the apparatuses that generate an input signal input to thesynchronization circuit include the displacement sensor 16 and thedisplacement sensor 20.

To achieve the synchronization circuit according to the presentexemplary embodiment, a field programmable gate array (FPGA) or anapplication specific integrated circuit (ASIC) can be used. By using aFPGA or an ASIC, a plurality of control circuits (23, 101, 102, and 103)can be implemented in an integrated circuit. Thus, the control timing ofthe control circuits can be accurately adjusted at high speed.

The displacement calculation devices 23 measure the frequencies, theamplitudes, and the phases of vibration of the probe 1 and the stageusing the electric signal output from the displacement sensor 16 and thedisplacement sensor 20. In addition, the displacement calculationdevices 23 output signals for controlling the vibration of the probe 1and the Z stage 9 to the voltage applying apparatus 12 and the specimenstage control device 11. The voltage signal is one of a triangle wavesignal, a square wave signal, a sine wave signal, and a cosine wavesignal. The displacement calculation device 23 for vibration of theprobe 1 includes a circuit that generates a signal for controllingvibration of the probe 1, and the displacement calculation device 23 forvibration of the Z stage 9 includes a circuit that generates a signalfor controlling vibration of the Z stage 9. The displacement calculationdevices 23 may be provided as independent circuits for the probe 1 andthe Z stage 9. Alternatively, the displacement calculation devices 23may be provided in the same circuit board.

Each of the displacement calculation devices 23 includes a feedbackcircuit that makes the phase difference between each of a signal outputfrom the displacement sensor 16 and the displacement sensor 20, whichcorrespond to the actual vibration of the probe 1 and the Z stage 9, anda voltage signal generated on the basis of a reference clock generatedby the reference clock generating circuit 101 zero. When the feedbackcircuit operates, the probe 1 and the Z stage 9 vibrate at a constantfrequency and with a constant phase difference. Such a drive mechanismis generally referred to as a phase locked loop (PLL). In addition, byproviding a delay compensation circuit in the PLL circuit, a voltagesignal having a desired delay time with respect to the reference signalcan be generated.

The output signals output from the displacement sensor 16, thedisplacement sensor 20, and the displacement calculation device 23 arealso input to the signal selection switch 102. The signal selectionswitch 102 selects one of the output signals output from thedisplacement sensor 16 and the displacement calculation device 23 andinputs the selected signal to the gate signal generating circuit 103.

The gate signal generating circuit 103 can use the input signal as areference signal. Thus, the gate signal generating circuit 103 can beset up so as to output a particular voltage signal for a period of timefor which the voltage value of the reference signal exceeds apredetermined threshold value. In addition, a desired delay time can beset so that the output time of the voltage is extended from the periodof time for which the voltage value of the reference signal exceeds apredetermined threshold value forward and backward in the timedirection. According to the present exemplary embodiment, ionizationoccurs during a period of time for which the reference signal exceedsthe threshold value. However, if the polarity of each of the outputsignals of the displacement sensors and the displacement calculationdevice 23 is reversed, the voltage signal may be output for a period oftime for which the voltage value of the reference signal is less thanthe threshold value. The voltage signal is one of a positive voltage, anegative voltage, and 0 volt.

The output signal generated by the gate signal generating circuit 103 isinput as the gate voltage signal of the ion counter 104. Setup isperformed so that the ion counter 104 operates for a period of time forwhich the gate signal is being output.

A method for storing the voltage signal output from the ion counter 104as digital data is described below. The signal output from the ioncounter 104 is analog-to-digital (A/D) converted and is stored in theprimary memory 105 for a predetermined period of time. The measurementdata corresponding to the type of ion to be measure are selected and arestored in the storage 107 formed from a hard disk drive (HDD) or a solidstate drive (SSD). The process for selecting the data is performed inthe data filter 106 by a computer program. Thereafter, the primarymemory 105 is overwritten with new data. Alternatively, the new data iswritten in another area. By selecting data and storing the data in thestorage 107, the total amount of data can be reduced. If ions to bemeasured are predetermined, the method can be applied. In contrast, ifions that are not predetermined are detected, all the data obtained bythe data filter 106 can be stored in the storage 107.

Note that the above-described synchronization method is employed whenboth the probe 1 and Z stage 9 vibrate. However, when one of the probe 1and the Z stage 9 vibrates, a gate signal is generated by stopping thedisplacement calculation device 23 for vibration of the probe 1 or the Zstage 9 and the downstream control device and inputting the outputsignals output from the driven displacement calculation device 23 anddisplacement sensor to the signal selection switch 102.

Third Exemplary Embodiment

According to a third exemplary embodiment, the ionization deviceincludes a holding table for holding a specimen, a probe for identifyinga portion of the specimen to be ionized, an ion extraction electrode forextracting ions generated by ionizing the specimen, a liquid supplyingunit for supplying liquid to form a liquid bridge between the specimenand the probe, and a voltage applying unit for applying a voltage to aportion of the probe between a portion in contact with the liquid bridgeand the ion extraction electrode.

In addition, the ionization device includes a vibrating unit that causesat least the probe to repeatedly move close to and away from the holdingtable. The vibrating unit causes the probe to vibrate at one of at leasttwo frequencies, one of which is the frequency for forming a liquidbridge and the other is a frequency higher than that frequency.

FIG. 6 is a schematic illustration of an imaging system including theionization device according to the third exemplary embodiment. Theimaging system includes a probe 201 having a flow passage therein, wherethe flow passage allows liquid to flow through, a probe vibrating unit202 that vibrates the probe 201, a solid specimen 203, a liquid bridge204 formed between the probe 201 and the solid specimen 203, a Taylorcone 205, charged fine liquid droplets 206, an ion entrapment unit 207having an ion extraction electrode for entrapping ions into a massspectrometry apparatus, an XY stage 208 serving as a holding table thatholds the solid specimen 203, a Z stage 209 for moving the solidspecimen 203 serving as a holding table vibrating unit in the verticaldirection (a Z direction) in FIG. 6, specimen stage control units 210and 211 serving as signal transmitters for transmitting vibrationsignals to the stages, a voltage applying unit 212, a liquid supply unit213 that supplies liquid to the probe 201, a voltage applying unit 214,light sources 215 and 219, displacement sensors 216 and 220, a massspectrometry unit 217, a voltage applying unit 218, an image informationgenerating unit 221, a displacement calculation unit 222, and a displayunit 223.

According to the present exemplary embodiment, liquid supplied from theliquid supply unit 213 forms the liquid bridge 204 between the solidspecimen 203 and the probe 201. The solid specimen 203 is an objectformed from an object to be measured that is placed on one of a metalsubstrate, an insulating material substrate, and a semiconductorsubstrate. The object to be measured requires that the componentdistribution in the microregion of, for example, a biological tissue orbodily fluid is measured. In addition, part of the liquid that forms theliquid bridge 204 is turned into charged fine liquid droplets 206 by thevibration of the probe 201 and an electric field generated by thevoltage applying unit 214 and the voltage applying unit 218, where thevoltage applying unit 214 applies a voltage between a portion of theprobe 201 in contact with the liquid bridge 4 and the ion extractionelectrode. Thus, the charged fine liquid droplets 206 move away from theprobe 201. The solvent components of the charged fine liquid droplets206 that move away from the probe 201 are evaporated and, thus, thecomponent to be measured can be entrapped in the ion entrapment unit 207in the form of ions. That is, according to the present exemplaryembodiment, the probe 201 functions as a supply unit for supplyingliquid onto the substrate and an acquiring unit of the substance, atransport unit for transporting the liquid to a position that issuitable for ionization, and a forming unit for forming a Taylor cone205 for ionization.

The liquid supply unit 213 supplies the solvent for dissolving acomponent to be analyzed contained in the solid specimen 203 or mixedsolution of a component to be analyzed and the solvent (hereinafter, thesolvent and the mixed solution are collectively and simply referred toas “liquid”). The liquid supplied from the liquid supply unit 213 is ledto the flow passage in the probe 201. At that time, a voltage is appliedto the liquid by the voltage applying unit 214. The voltage applied tothe liquid is one of a DC voltage, an AC voltage, a pulse voltage, andzero volt.

The configurations of the probe 201 and a connection pipe that connectsthe probe 201 to the liquid supply unit 213 are similar to those of theabove-described exemplary embodiments.

The liquid supplied from the liquid supply unit 213 is supplied from thetop end of the probe 201 onto the solid specimen 203. In this manner, aminutely small amount of the substance contained in the solid specimen203 can be ionized in an atmospheric pressure environment.

In the above-described configuration according to the present exemplaryembodiment, the probe 201 is also vibrated. Note that according to thepresent exemplary embodiment, the vibration of the probe 201 is theperiodic motion of the probe 201 such that the position of the top endof the probe 201 adjacent to the solid specimen 203 is spatiallydisplaced. In particular, it is desirable that the probe 201 isbending-vibrated in a direction crossing the axis direction of the probe201. In addition, it is desirable that the probe 201 be vibrated due tomechanical vibration provided from the probe vibrating unit 202.

The frequency and amplitude of the vibration of the probe 201 may be setto desired values. The values may be constant values or modulatedvalues. For example, by varying a voltage value or a frequency valueoutput from the voltage applying unit 212 that is electrically connectedto the probe vibrating unit 202, the amplitude and frequency of thevibration of the probe 201 can be adjusted to the desired values.

The Z stage 209 is used to bear the solid specimen 203 and vibrate thesolid specimen 203 in a direction perpendicular to the surface of thesolid specimen 203. The Z stage 209 can vibrate on the basis of acontrol signal output from the specimen stage control unit 211 connectedto the Z stage 209. The frequency and amplitude of the vibration may beset to desired values. The values may be constant values or modulatedvalues. In such a case, by varying a voltage value or a frequency valueoutput from the specimen stage control unit 211, the amplitude andfrequency of the vibration can be adjusted to the desired values.

Like the first exemplary embodiment, the light source 215 and thedisplacement sensor 216 serve as a displacement measuring unit used tomeasure the vibration of the probe 201.

Similarly, the light source 219 and the displacement sensor 220 serve asa displacement measuring unit used to measure the vibration of the XYstage 208 and the Z stage 209.

The electric signals output from the displacement sensor 216 and thedisplacement sensor 220 are input to the displacement calculation unit222. The frequency, the amplitude, and the phase of the vibration of theprobe and the stage can be measured using the electric signals.

According to the present exemplary embodiment, a vibration unit thatvibrates the probe is independent from a vibration unit that vibratesthe specimen. Accordingly, the following three vibratory modes can beprovided as a drive mode.

That is, the three vibratory modes are (D) a mode for vibrating theprobe, (E) a mode for vibrating the solid specimen, and (F) a mode forindependently vibrating the probe and the solid specimen at the sametime.

FIG. 6 illustrates the drive modes (D) and (F). In the drive mode (E),provision of a signal from the voltage applying unit 212 to the probevibrating unit 202 is stopped, and the probe 201 is located in closeproximity to the solid specimen 203 or is in contact with the solidspecimen 203.

In the drive mode (D) in which only the probe 201 is vibrated, a signalis input to the probe vibrating unit 202, and provision of a signal tothe specimen stage control unit 211 is stopped. As a result, the probe201 vibrates, and the vibration of the Z stage 209 is stopped.

In the drive mode (E) in which the solid specimen 203 is vibrated,provision of a signal to the probe vibrating unit 202 is stopped, and asignal is input to the specimen stage control unit 211. As a result, theprobe 201 is stopped, and the Z stage 209 vibrates. If the probe 201 isin contact with a surface of the solid specimen 203, vibration of the Zstage 209 propagates to the probe 201. Accordingly, the probe 201 can bevibrated. Even in such a case, the drive mode (E) is applied.

In the drive mode (F) in which the probe 201 and the solid specimen 203are independently vibrated, a signal is input to the probe vibratingunit 202. At the same time, a signal is input to the specimen stagecontrol unit 211. As a result, the probe 201 and the Z stage 209independently vibrate.

If the drive modes (D) and (E) are selected, the amplitudes of vibrationof the probe 201 and the Z stage 209 are modulated, respectively. FIGS.7A and 7B illustrate examples of the amplitude modulation in the drivemodes (D) and (E).

When the drive mode (D) is selected, the amplitude of vibrationcorresponds to a time variation of the input signal input to the probe201. When the drive mode (E) is performed, the amplitude of vibrationcorresponds to a time variation of the input signal input to the Z stage209. There is a correspondence between the input signal and theamplitude of each of the probe 201 and the Z stage 209. Accordingly, bymeasuring the input signal, the amplitude of each of the probe 201 andthe Z stage 209 can be estimated.

FIGS. 7A and 7B illustrate different input signal patterns. In FIG. 7A,a waveform obtained by combining a sine wave and a square wave isillustrated. In FIG. 7B, a waveform obtained by combining a sine waveand a triangle wave is illustrated. In such a case, a sine wave is usedas a fundamental vibration signal, and a square wave or a triangle waveis used as a vibration signal for modulation. Thus, the combined signalis generated. To generate the combined signal, the two types of signalare multiplied together, and the product is used as the combined signal.However, addition, subtraction, or division and any combination thereofcan be employed to generate the combined signal. The frequency of thefundamental vibration signal is set so as to be the same as theresonance frequency of the probe 201 or the Z stage 209. In addition,the frequency of the vibration signal for modulation is set so as to bethe same as the frequency used for generating the liquid bridge 204. Itis desirable that two types of signal be selected from among a trianglewave signal, a sine wave signal, a square wave signal, and a saw-toothwave signal as the fundamental vibration signal and the vibration signalfor modulation.

In addition, it is desirable that the frequency of one of the twovibration signals be an integral multiple (2 or more) of the frequencyof the other vibration signal, and the phase difference between thevibration indicated by one of the vibration signals and the vibrationindicated by the other vibration signal be 0 or 180 degrees.

That is, according to the present exemplary embodiment, the vibratingunit is a probe vibrating unit for vibrating the probe. A configurationto reduce the frequency used for forming the liquid bridge to an integerfraction of the frequency of vibration of the probe by modulating theamplitude of vibration of the probe is provided.

Setup is made so that at times 201 and 203 at which the absolute valueof the amplitude is maximized, the probe 201 is located so as to be theclosest to the solid specimen 203. In a time window around each of thetimes 201 and 203, the liquid bridge 204 is formed between the probe 201and the solid specimen 203, and ionization is performed. In contrast, inthe durations 202 and 204 for which the amplitude is small, the liquidbridge 204 is not formed between the probe 201 and the solid specimen203 and, thus, the component of the solid specimen is not ionized. Inthis manner, by adjusting the modulation frequency of the vibrationamplitude, the number of formation processes of the liquid bridge 204can be controlled. The liquid bridge 204 is formed at the time 201 andthe times 203, and the component contained in the surface of the solidspecimen 203 is dissolved in the liquid deposited to the top end of theprobe 201. The component is ionized in the durations 202 or thedurations 204. Since the solvent continuously flows into the probe 201even in the duration 202 and the duration 204, the liquid deposited ontothe top end of the probe 201 is diluted by the solvent. The componentcontained in the surface of the solid specimen 203 is ionized over timeand, thus, the component in the liquid disappears. In addition, the topend of the probe 201 is cleaned by the solvent that newly flows into theprobe 201. As described above, by modulating the vibration amplitude,each of the duration in which the liquid bridge 204 is formed and theduration in which the liquid bridge 204 is not formed can be set to adesired value. As a result, unlike Tapping-mode SPESI described inNon-patent literature above, carry-over can be prevented.

If the drive mode (F) is selected, two types of vibration signal (i.e.,a signal for vibration of a probe transmitted to the probe vibratingunit 202 and a signal for vibration of a holding table transmitted tothe holding table vibrating unit are employed. Thus, the probe 201 andthe Z stage 209 vibrate at their own frequencies. At that time, it isdesirable that the frequency of vibration of the probe 201 be anintegral multiple (2 or more) of the frequency of the Z stage 209, whichis the vibrating unit of the holding table, and the phase differencebetween the vibration of the probe 201 and the vibration of the Z stage209 be 0 or 180 degrees. FIG. 8 illustrate an example of the vibrationsignals input to the probe 201 and the Z stage 209.

In this example, signals input to the specimen stage control unit 211and the voltage applying unit 212 are illustrated. Note that in thisexample, the frequency of vibration of the probe 201 is 5 times thefrequency of vibration of the Z stage 209. Accordingly, the Z stage 209moves closest to the probe 201 once every five vibrations of the probe201. A waveform chart (a) of FIG. 8 illustrates the input signal inputto the probe 201. Waveform charts (b), (c), and (d) of FIG. 8 illustrateexamples of the input signals input to the Z stage 209. In the waveformchart (a) of FIG. 8, the ordinate is correlated with the position of theprobe 201 in the Z direction. As can be seen from the waveform chart (a)in FIG. 8, the probe 201 vibrates between a state 1 in which the probe201 is the closest to the solid specimen 3 and a state 2 in which theprobe 201 is the closest to the ion entrapment unit 207. The ordinatesin waveform charts (b), (c), and (d) of FIG. 8 are correlated with theposition of the surface of the solid specimen 203 in the Z direction. Ascan be seen from the waveform charts (b), (c), and (d) of FIG. 8, theprobe 201 vibrates between a state 4 in which the probe 201 is theclosest to the solid specimen 3 and, thus, a liquid bridge is formed anda state 3 in which the solid specimen 203 moves away from the probe 201and, thus, the liquid bridge 204 disappears.

In a time window around the time 201 at which the probe 201 is locatedclosest to the solid specimen 203, a liquid bridge is formed between theprobe 201 and the solid specimen 203, and ionization occurs. In theother time window, a liquid bridge is not formed and, thus, thecomponent of the solid specimen is not ionized. As described above, byindependently adjusting the frequencies of vibration of the probe 201and the Z stage 209, each of the duration in which a liquid bridge isformed and the duration in which a liquid bridge is not formed can beset to a desired value. Thus, carry-over can be prevented. According tothe present exemplary embodiment, in addition to advantages that are thesame as in the above-described drive modes (D) and (E), an advantagethat the absolute value of the distance between the probe 1 and the Zstage 9 is increased due to vibration of both the probe 201 and Z stage209 can be provided. Note that it is desirable that the presentexemplary embodiment be applied when the irregularity of the surfaceprofile of the solid specimen 203 is significant and, thus, thevibration amplitude of the probe 201 is increased so that formation ofthe liquid bridge 204 and ionization are stably performed. While thepresent exemplary embodiment has been described with reference to thecontrol signals of the specimen stage control unit 211 and the voltageapplying unit 212 being a triangle wave, a sine wave, or a square wave,the waveform is not limited thereto. For example, the waveform may be asawtooth waveform or a waveform obtained by combining a triangle wave, asine wave, a square wave, and a sawtooth wave illustrated in FIG. 7B.

In each of the drive modes (D), (E), and (F), the vibration state ismeasured by using the displacement calculation unit 122. Thereafter,control signals are output from the displacement calculation unit 222 tothe specimen stage control unit 211 and the voltage applying unit 212 sothat a desired vibration state is obtained. At that time, by providing afeedback circuit in the displacement calculation unit 222, a stablevibration condition can be automatically maintained. In addition, aslight timing shift may occur between vibration of the probe 201 andvibration of the Z stage 209 due to, for example, electrical wiringbetween the parts and the electric capacitances of the parts illustratedin FIG. 6. In such a case, by providing a delay circuit that controlsthe timing in the feedback circuit, the timing shift between actualvibration of the probe 201 and a control signal and the timing shiftbetween actual vibration of the Z stage 209 and a control signal can becompensated for.

According to the present exemplary embodiment, by using one of the drivemodes (D), (E), and (F), the following processes are alternatelyperformed: (i) a process to supply liquid from a probe onto a solidspecimen and form a liquid bridge containing the substance between theprobe and the solid specimen, and (ii) a process to generate an electricfield for generating ions between the conductive portion of the probe incontact with the liquid and an ion extraction electrode. That is, bychanging the position of one end of the probe that vibrates, an optimumpositional relationship can be set in each of the processes (i) and(ii). In terms of the timing of formation of the liquid bridge, in thedrive mode (D), the liquid bridge is formed at a frequency lower thanthe resonance frequency of the probe. In the drive mode (E), the liquidbridge is formed at a frequency lower than the resonance frequency ofthe Z stage. In the drive mode (F), the liquid bridge is formed at afrequency lower than each of the probe and the Z stage.

By intermittently or continuously providing the liquid from the probe201, the liquid bridge 204 is formed.

When the probe 201 moves away from the solid specimen 203 due to thevibration, liquid that forms the liquid bridge 204 moves closer to theion entrapment unit 207 including the ion extraction electrodeelectrically connected to the voltage applying unit 218. At that time,the liquid moves to the side surface of the probe 201 adjacent to theion entrapment unit 207 to form the Taylor cone 205 due to the potentialdifference between the electric potential of the liquid having thevoltage applied thereto and the electric potential of the ion extractionelectrode having the voltage applied by the voltage applying unit 218(preferably 0.1 kV or higher and 10 kV or lower and, more preferably, 3kV or higher and 5 kV or lower).

The magnitude of the electric field increases in the top end portion ofthe Taylor cone 205 and, thus, electrospray is generated from the mixedsolution. Accordingly, fine charged liquid droplets 206 are generated.

The ion entrapment unit 207 is heated at a particular temperaturebetween a room temperature and several hundred degrees. In addition, avoltage is applied to the ion entrapment unit 207.

Subsequently, the ions are introduced into the mass spectrometry unit217 connected to the ion entrapment unit 207 through a differentialexhaust system, and the mass-to-charge ratio of the ions is measured inthe mass spectrometry unit 217.

In addition, by measuring a correlation between the mass-to-charge ratio(mass number/charge number) of the ions and the amount of generatedions, the mass spectrum can be obtained.

According to the present exemplary embodiment, unlike the case in whichone of a probe and a Z stage is vibrated with a constant amplitude andat a constant frequency and, in addition, the number of vibrations perunit time is the same as the number of formation processes of the liquidbridge, carry-over can be prevented.

In addition, to fix a specimen onto the substrate and ionize thespecimen, the coordinates of the position of a portion of the specimento be ionized can be controlled by changing the position of the XY stage208 using the specimen stage control unit 210. Furthermore, byassociating the coordinates of the ionized positions (positionalinformation) with the obtained mass spectra, the two-dimensionaldistribution of the mass spectrum can be obtained. Data obtained usingthis technique is three-dimensional data containing the coordinates (anX coordinate and a Y coordinate) of the ionized position and the massspectrum. After the ionization and the mass spectrum acquisition areperformed at different positions, the amount of ions having a desiredmass-to-charge ratio is selected, and the distribution thereof isdisplayed. In this manner, a mass image can be obtained for each of thecomponents, and the distribution of a particular component across thesurface of the specimen can be captured. The specimen can be moved sothat the liquid bridge 204 formed by the probe 201 scans a desired planeto be measured.

Waveform charts (a) to (e) of FIG. 9 illustrate the timing of drivingthe probe 201, the Z stage 209, and the XY stage 208 in the drive modes(D), (E), and (F). The waveform chart (a) of FIG. 9 illustrates thepattern of an input signal input to the probe 201 or the Z stage 209 inthe drive mode (D) or (E). The waveform chart (b) of FIG. 9 illustratesthe pattern of a signal input to the XY stage 208 in the drive mode (D)or (E). As in FIGS. 7A and 7B, the liquid bridge 204 is formed in thetime window around the time 201. Thereafter, the liquid bridge 204disappears, and ionization occurs. Subsequently, at the time 202, asignal is input to the XY stage 208 and, thus, the position in thesurface of the solid specimen 203 to be analyzed is moved.

The waveform chart (c) of FIG. 9 illustrates the pattern of an inputsignal input to the probe 201 in the drive mode (F). The waveform chart(d) of FIG. 9 illustrates the pattern of an input signal input to the Zstage 209 in the drive mode (F). The waveform chart (e) of FIG. 9illustrates the pattern of an input signal input to the XY stage 208 inthe drive mode (F). As in the waveform charts (a) to (d) of FIG. 8, theliquid bridge 204 is formed in the time window around the time 201.Thereafter, the liquid bridge 204 disappears, and ionization occurs.Subsequently, at the time 202, a signal is input to the XY stage 208and, thus, the position in the surface of the solid specimen 203 to beanalyzed is moved. By adjusting the time 202 so that the componentdissolved in the liquid bridge 204 is ionized between the time 201 andthe time 202 in this manner, carry-over in the liquid bridge 204 formedafter the time 202 can be prevented.

The displacement calculation unit 222 identifies a portion of thesurface of the solid specimen 203 to be ionized. That is, thedisplacement calculation unit 222 identifies a portion of the surface ofthe solid specimen 203 to be analyzed by the mass spectrometry unit 217.Thereafter, the displacement calculation unit 222 can move the solidspecimen 203 using the XY stage 208 and the Z stage 209 so that thesubstance contained in the portion is included in the Taylor cone 205via the liquid bridge 204. The displacement calculation unit 222 isformed from, for example, a computer. The displacement calculation unit222 receives at least a signal output from the displacement sensor 216and outputs signals to the voltage applying unit 212, the specimen stagecontrol unit 210, and the specimen stage control unit 211.

According to the present exemplary embodiment, the image informationgenerating unit 221 connected to the mass spectrometry unit 217generates image information used for displaying, as an image, thedistribution of a substance contained in the solid specimen 203 frominformation regarding the position of the solid specimen 203 to beanalyzed (a portion of the solid specimen 203 to be analyzed) receivedfrom the displacement calculation unit 222 and the mass information (theinformation regarding the signal intensity of the mass spectrum)obtained from the mass spectrometry unit 217 according to theabove-described present exemplary embodiment.

According to the present exemplary embodiment, the imaging systemincludes the mass spectrometry apparatus according to theabove-described present exemplary embodiment as a mass spectrometryapparatus unit. The imaging system further includes the imageinformation generating unit and the image display unit.

The image information output from an output sub-unit of the imageinformation generating unit 221 is input to the display unit 223, suchas a flat panel display, connected to the image information generatingunit 221. Thus, the image is displayed. The image information may betwo-dimensional image information or three-dimensional imageinformation.

As described above, a substance that is dissolved from a particularposition of the solid specimen 203 into the liquid bridge 204 can bedetected on the basis of the result of mass spectrometry at theparticular position of the solid specimen 203. By changing theparticular position in the surface of the solid specimen 203 andperforming mass spectrometry at the position, mass spectrum data can beobtained. By combining the mass spectrum data with the informationregarding the particular position, the distribution of the substance inthe solid specimen 203 (in most cases, the distribution of the substanceacross the surface of the solid specimen 203) is obtained and isdisplayed (superimposed) as an image.

In addition to the position of the substance, the amount of thesubstance is displayed. The amount of the substance is represented by acolor or the brightness of the image. In addition, if multiplesubstances contained in the solid specimen 203 are analyzed, thesubstances can be identified by using different colors, and the amountthereof can be represented by the brightness thereof. Furthermore, apre-captured microscope image of the solid specimen 203 may besuperimposed on the image regarding the mass of the solid specimen 203and may be displayed.

While the present invention has been described with reference toexemplary embodiments, it is to be understood that the invention is notlimited to the disclosed exemplary embodiments. The scope of thefollowing claims is to be accorded the broadest interpretation so as toencompass all such modifications and equivalent structures andfunctions.

What is claimed is:
 1. An ionization device comprising: a holding tableconfigured to hold a specimen to be ionized; a probe configured toidentify a portion of the specimen to be ionized; an ion extractionelectrode configured to extract ions obtained by ionizing the specimen;a liquid supplying unit configured to supply liquid to between thespecimen and the probe to form a liquid bridge between the specimen andthe probe; an electric field generating unit configured to generate anelectric field between the probe and the ion extraction electrode; avibrating unit configured to vibrate one of the probe and the holdingtable; a measuring unit configured to measure a vibration state ofvibration of at least one of the probe and the holding table and outputa signal of the vibration state; a displacement calculation unitconfigured to input the signal of the vibration state, and output acontrol signal to the vibrating unit; and a feedback circuit configuredto maintain vibration of at least one of the probe and the holding tableaccording to the signal of the vibration state.
 2. The ionization deviceaccording to claim 1, wherein the displacement calculation unit has thefeedback circuit.
 3. The ionization device according to claim 1, whereinthe vibration state is amplitude and a frequency of the vibration. 4.The ionization device according to claim 1, wherein the vibrating unitrepeatedly moves the probe close to the holding table and moves theprobe away from the holding table.
 5. The ionization device according toclaim 1, wherein the feedback circuit is configured to calculate a shiftof the input signal from the measuring unit from a reference signal inthe displacement calculation unit, generate a signal that corrects theshift, and output the signal to the vibrating unit.
 6. A massspectrometry apparatus comprising: a holding table configured to hold aspecimen to be ionized; a probe configured to identify a portion of thespecimen to be ionized; an ion extraction electrode configured toextract ions obtained by ionizing the specimen; a liquid supplying unitconfigured to supply liquid to between the specimen and the probe toform a liquid bridge between the specimen and the probe; a vibratingunit configured to vibrate one of the probe and the holding table; anelectric field generating unit configured to generate an electric fieldbetween the probe and the ion extraction electrode; a mass spectrometryunit configured to mass analyze ions extracted by the ion extractionelectrode; a measuring unit configured to measure a vibration state ofvibration of at least one of the probe and the holding table and outputa signal of the vibration state; a displacement calculation unitconfigured to input the signal of the vibration state, and output acontrol signal to the vibrating unit; and a feedback circuit configuredto maintain vibration of at least one of the probe and the holding tableaccording to the signal of the vibration state.
 7. The mass spectrometryapparatus according to claim 6, wherein the vibration state is amplitudeand a frequency of the vibration.
 8. The mass spectrometry apparatusaccording to claim 6, wherein the vibrating unit repeatedly moves theprobe close to the holding table and moves the probe away from theholding table.
 9. The mass spectrometry apparatus according to claim 6,wherein the feedback circuit is configured to calculate a shift of theinput signal from the measuring unit from a reference signal in thedisplacement calculation unit, generate a signal that corrects theshift, and output the signal to the vibrating unit.
 10. The massspectrometry apparatus according to claim 6, further comprising: ascanning unit configured to scan the probe relative to a surface of thespecimen.
 11. An imaging system comprising: the mass spectrometryapparatus according to claim 6; an image forming unit configured to formimage information used for imaging distribution of a component of asubstance contained in a specimen using mass information analyzed by themass spectrometry apparatus and information regarding a position in thespecimen; and an output unit configured to output the image information.